Open AccessModeling of mechanical behavior in additive manufacturing at part scale
Author(s) -
Qiang Chen,
Erwan Beauchesne,
F. Arnaudeau,
PierreRichard Dahoo,
Constantin Meis
Publication year - 2019
Publication title -
journal of physics. conference series
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.21
H-Index - 85
eISSN - 1742-6596
pISSN - 1742-6588
DOI - 10.1088/1742-6596/1391/1/012010
Subject(s) - residual stress , distortion (music) , materials science , scale (ratio) , constitutive equation , finite element method , process (computing) , mechanical engineering , computer simulation , domain (mathematical analysis) , mechanics , computer science , structural engineering , composite material , engineering , mathematics , mathematical analysis , physics , cmos , quantum mechanics , operating system , amplifier , optoelectronics
Laser Beam Melting is actually capable of producing parts with reliable mechanical properties. However, efficient production still remains a challenge and high quality numerical simulation is required in order to understand the physical mechanisms involved. Consequently, a macroscopic numerical model at part scale is actually under development for understanding the relationship between different process and material parameters with the mechanical state of final parts such as distortion and residual stress. Classical finite element method is used to solve the coupled thermo-mechanical problem on the whole domain defined by the workpiece, the baseplate and the support structures. At this scale, powder packing is neglected as well as the hydrodynamics behavior within the melt pool. Homogeneous equivalent heat source is used and imposed until several layers below the current deposited layer. Elastoplastic constitutive material law with temperature dependent parameters has been developed.